SU1291704A1 - Extraction steam turbine unit - Google Patents

Abstract

This invention relates to a power system. The invention makes it possible to increase the economy by reducing the consumption of 3231 electricity for its own needs and reliability. In the condensation mode of operation of the unit, the water in the turbine (G) 15 is discharged through the outlet of the pipeline (T) 21 and the additional T26 to G 16. It goes to the deaerator 12 from the latter. valves 23, 27 are closed, and valves 24, 28 are open. In the heat extraction mode, the valves 23, 27 are opened, and the valves 24, 28 are closed. The waves that have been worked out by Г 16 are retracted w, it is T 22 and the additional T 25 arrives at Г 15. From the last, T 21 is sent to deaerator 12. Adjustment of revolutions of G in the indicated modes is carried out through bypassing T 29, 30 s valves 31, 32. 1 Il. (Lu so | about

Description

The invention relates to a power system and can be used in steam heat turbine plants.

The purpose of the invention is to increase efficiency by reducing auxiliary power consumption and reliability.

The drawing shows a diagram of the heat and steam turbine installation.

The heat-producing steam turbine of the installer 2 enters the condenser 3 and the network heater 4, where it is condensed to transfer heat to the cooling and network water.

The resulting condensate is pumped by the condensate pumping pump, by them pumps 8 and 9 through regulators 10 and 11, maintaining a predetermined water level in the condenser 3 and the network heater 4, and low pressure heaters 5 and 6

The kit contains a steam generator 1, a steam deaerator 12 in which it supports a turbine 2, a condenser 3, and a network preheat with a pressure of about 6 kgf / cm.

Water from the deaerator under high pressure (180–200 kgc / cm) is pumped by the feed pump 13 through the high pressure preheater 7 to the steam generator 1.

A portion of the water pumped by the pump 13 through supply lines 17 and 18 is supplied to the hydro turbines 15 and 16 of pumps 8 and 9 in an amount and sequence determined by the operating mode of the installation in accordance with the power consumption and the condensate drive 8 and pumping pumps for 9 condensation and heat pumps are made in the form of hydro turbines 15 and 16, the receiving pipes of the short pipes are connected to the inlet pipelines 17 and 18 with

4, low-pressure condensate heaters 5 and 6, high-pressure feed water heater 7, condensate 8 and pump 9 pumping, connected respectively through regulators 10 and 11 of the condensate flow to deaerator 12, feed pump 13 connected by a pressure head through pipe 14 through a high pressure preheater 7 with a steam generator 1.

licensing regimes.

In the condensation mode of the plant, the power consumption and speed of the turbine 15 of the pump 8 is higher than that of the crankshaft 19 and 20 "of the large 25 coca 9 revolutions. Therefore, the hydro turbine 15 is connected to the pressure pipe 14 to the high pressure preheater 7, and the discharge pipes are connected to pipelines 21 and 22 with valves 23 and 24 installed on them and connected to deaerator 12.

The inlet pipes 17 and 18 are connected by means of additional pipes 25 and 26 with the valves 27 and 28, respectively, with the outlet pipes 21 and 22, and

The feed water is supplied through the pipeline 17 through the valve 19 at high revolutions in an amount determined by the flow of condensate through the regulator 10, measured by the sensor 34, transmitting the control signal 30 to the valve 19. In the indicated mode, the valves 23 and 27 are closed and the valves 24 and 28 are open.

The water worked out in the hydroturbine 15 comes along the outlet 21 and an additional 26 pipelines into the hydroturbine 16

additional pipes 25 and 26 are provided with 5 (the valve 20 is closed) and along the outlet pipe by bypass pipe 29 to pipe 22 is directed to the deaera- and 30

with installed on them, valves 31 and 32 "low speed hydro turbines 15 and 16 connected to the pipeline 33 drain.

The valves 19, 31 and 20 and 32 are equipped with differential sensors 34, on which a control signal is formed according to the value of the differential pressure on the regulators 10 and 11. Thus, using

torus 12. Regulation of revolutions and power of the turbine 16 in the condensation mode of the installation is carried out by resetting Q through the bypass pipe 30 by a low-speed valve 32 "receiving a control signal from the sensor 34 measuring the pressure drop on the condenser regulator 11, pumped by the pump 9 from the network heaters 19, 31 and 20, 32 are fed to the hydro- 45 l 4.

rotary turbines 15 and 16 feed water in a co-thus, on the condensation relic, providing regulation of the hydro turbine press of condensate condensate pumps 8 and 9, depending on the flow of condensate.

The feed pump 13 is provided with a steam-turbine actuator 35, on the supply steam line to which the feed pump regulator 36 is installed, which controls the flow of steam to the feed pump turbine depending on the flow of feed water to the installation.

The installation works as follows.

The steam generated in the steam generator 1 is expanded in the flow section of the turbogenerator 50

55

Sa 8 is connected to feed water directly to pressure feed line 14, and hydroturbine 16 of transfer pump 9 is sequentially behind hydro turbine 15. At the same time, feedwater flow from pump 13 to hydro turbine 15 and 16 is determined only by the power consumption of hydro turbine 15, and the pressure drop feed water on valves 19 and 32, as well as on hydro turbines 15 and 16, is set in accordance with the power distribution of pumps 8 and 9.

torus 2 and enters the condenser 3 and the network heater 4, where it is condensed to transfer heat to the cooling and network water.

The resulting condensate is pumped by the condensate pumping pump, by them pumps 8 and 9 through regulators 10 and 11, maintaining a predetermined water level in the condenser 3 and the network heater 4, and low pressure heaters 5 and 6

 rota pumps on condensation and heat

licensing regimes.

In the condensation mode of the plant, the power consumption and speed of the turbine 15 of the pump 8 is higher than that of the coca 9. Therefore, the turbine 15 is supplied with feed water through the pipeline 17 through the valve 19 "large revolutions in the amount determined by the condensate consumption through the regulator 10, measured A sensor 34 that transmits a control signal to the valve 19. In this mode, the valves 23 and 27 are closed and the valves 24 and 28 are open.

The water worked out in the hydroturbine 15 comes along the outlet 21 and an additional 26 pipelines into the hydroturbine 16

(valve 20 is closed) and through the discharge pipe 22 is directed to the deaerator

(valve 20 is closed) and through the discharge pipe 22 is directed to the deaerator

torus 12. Regulation of revolutions and power of the turbine 16 in the condensation mode of the installation is carried out by flushing the water through the bypass pipe 30 by a low-speed valve 32 "receiving the control signal from the sensor 34 measuring the pressure drop on the condenser regulator 11 pumped through pump 9 from the network preheater 4.

Sa 8 is connected to feed water directly to pressure feed line 14, and hydroturbine 16 of transfer pump 9 is sequentially behind hydro turbine 15. At the same time, feedwater flow from pump 13 to hydro turbine 15 and 16 is determined only by the power consumption of hydro turbine 15, and the pressure drop feed water on valves 19 and 32, as well as on hydro turbines 15 and 16, is set in accordance with the power distribution of pumps 8 and 9.

When switching from condensation to heat generation operation of the plant, the power consumption of the transfer pump 9 increases and that of condensate 8 decreases, the capacity of the feed pump 13 increases, corresponding to an increase in consumption by the steam turbine 2.

Accordingly, in the heat generation mode, the valves 23 and 27 are opened and the valves 24 and 28 are closed.

The coca 9 is connected via feedwater directly to the discharge feedline pipeline 14, and the hydroturbine 15 of the pump 8 is successively behind the hydro turbine 16. At the same time, the flow of feedwater from the pump 13 to the hydro turbines of both pumps is determined only by the power consumption of the hydro turbine 16 of the transfer pump 9. feedwater pressures on valves 20 and 31, as well as on

on the hydroturbine 16, the feed water is supplied to the underwater 10 hydro turbines 16 and 15 is set in

Directly through the pipe 18 and the valve 20, the high revolutions of the pump 9 in an amount determined by the flow of condensate through the controller 11, measured by the sensor 34, transmitting a control signal to maintain a constant pressure differential of the valve 20, and switching valves 19, 20, 27 and 28 is carried out remotely or automatically depending on the setting of the heating control unit 15

according to the distribution of power pumping and condensate pumps 9 and 8.

Claims (1)

Invention Formula A heat-generating steam-turbine unit containing a steam generator, a steam turbine with a condenser and a network heater equipped with a turbine load (not shown). 20 by condensate and pumping water in the hydroturbine 16, water flows through the pumps that have the drives, while the lead pipe 22 and the auxiliary pipe 25 are fed to the hydro turbine 15 (valve 19 is closed) and The pore pipes of both pumps are connected to the feedwater path, in which a deaerator with a drain pipe is placed, in order to increase deaerator 12. Regulation of speed and power-25 of economy and reliability, the drives of the constancy of the hydro turbine 15 on the heating condensation and transfer pumps of the unit's operating mode are completed in the form of hydro turbines with bypass and discharge of feed water through the bypass pipeline 29 by the valve 31 In addition to the hydraulic turbine 15, the low revolutions of the pump 8 to the deaerator 12. The valve 31 receives a control signal from the sensor 34, which measures the pressure drop of water on the controller 10 of the condensate flow pumped by the pump 8 from the condensate and 3. Thus, the heating mode pumping turbine 16 na35 piping, whereby the inlet and outlet of one turbine are connected respectively to the outlet and inlet of another hydroturbine with additional pipelines to which the bypass pipelines are connected with valves installed on them controlled by pressure differential in the feedwater path connected to the pipeline to the deaerator. The coca 9 is connected via feedwater directly to the discharge feedline pipeline 14, and the hydroturbine 15 of the pump 8 is successively behind the hydro turbine 16. At the same time, the flow of feedwater from the pump 13 to the hydro turbines of both pumps is determined only by the power consumption of the hydro turbine 16 of the transfer pump 9. and the differential feedwater pressures on valves 20 and 31, as well as on according to the distribution of power pumping and condensate pumps 9 and 8. 15 Invention Formula efficiency and reliability, the drives of condensate and transfer pumps are made in the form of hydroturbines with bypass piping, whereby the inlet and outlet of one turbine are connected respectively to the outlet and inlet of another hydroturbine with additional pipelines to which the bypass pipelines are connected with valves installed on them controlled by pressure differential in the feedwater path connected to the pipeline to the deaerator.